KR960002828B1 - Transponder antenna - Google Patents

Abstract

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Description

Transponder antenna

1 shows an object to be identified, a transponder attached to the object to transmit a signal to identify the object, and an antenna assembly at the transponder for the identification signal transmission.

2 is a plan view showing a conduction pattern on a first side of a dielectric member included in the antenna assembly.

3 is a bottom view showing the conduction pattern on the second side of the dielectric member included in the antenna assembly.

4 is a simplified electrical diagram of a first antenna included in an antenna assembly.

5 is a simplified electrical diagram illustrating the operation of the first antenna with antenna assembly.

The present invention relates to an antenna, and more particularly to an antenna operating at two widely separated frequencies. The antenna of the present invention is particularly adapted for use in transponders that make up a tag attached to an object, which makes the object identifiable by transmitting a signal identifying the object to the reader.

As trade becomes more complex, the capacity of products requiring individual identification increases. For example, a container containing goods is loaded onto a merchant ship, when the merchant ship arrives at the port of arrival, only one of the containers is unloaded, and the remaining containers remain on the merchant ship until they arrive at the next destination port. According to the remote principle of about 30 to 40 feet, it is necessary to identify the container to be unloaded at the destination port. By identifying the containers according to the remote principle, any help of the crew of the merchant ship or the dock worker at the port of destination, which must inspect the containers individually, can be eliminated.

Many systems have been developed to identify objects according to remote principles. Such a system includes a reader at a position displaced from the object to retrieve the transponder from the object. The transponder has an identification code depending on the object being searched for. This code is represented by a sequence of multiple binary "1s" and binary "0s" that are individual patterns for an object. Each of binary " 1 " and binary " 0 " of this sequence is converted into a number of signals sent to the reader. Each of the plurality of signals may have a first and second frequency that is a particular pattern to identify binary "1", or may have a first and second frequency that is another pattern to identify binary "0".

The transponder has an antenna (or antennas) for transmitting an identification signal to the reader. In accordance with government standards adopted in different regions of the world, there is a problem with transponders for antennas because signals are transmitted at different frequencies in different regions of the world. In the United States, Europe and Hong Kong, for example, the transmission frequency adopted by government regulations is approximately 915 MHz. In the Far East (excluding Hong Kong), the transmission frequency adopted by government regulations is approximately 2450 MHz.

Considerable efforts have been made and a large amount of money has been spent to provide a single transmission assembly, including a single antenna, capable of receiving and transmitting signals at two frequencies, respectively, as specified in the previous sentence. Despite these efforts and money consumption, no satisfactory antenna assembly has been provided to date.

The present invention provides a transmitter assembly useful for a transponder capable of receiving and transmitting signals at a first frequency of 915 MHz and a second frequency of 2450 MHz. The transmitter assembly includes a single antenna assembly that constitutes two antennas, each antenna being disposed on a single dielectric member and operable at a specific one of the frequencies. Each antenna is effective for receiving and transmitting signals at its own unique frequency.

To this end, the present invention, a thin planar dielectric member; A first degree material layer of a first region (located at the left end in the drawing) on the first surface which is one surface of the dielectric member; A second conduction of a second region (located at the right end in the drawing) on a second surface, which is another surface of the planar member, to constitute a first antenna operating at a first frequency together with the first conductive material layer Mulching layer; And a slot included in the first conductive material layer to constitute a conductive portion; The conducting portion extends from the first region to a position of a first surface opposite the second region on the second surface, the conductive portion extending along a surface of the dielectric member operating at a second frequency higher than the first frequency; It is characterized by being installed so as to move in one direction and cross each other.

In one embodiment of the invention, the dielectric member is thin and planar, and may have first and second opposing surfaces. Some layer of electrically conductive material is disposed on the first surface at one end of the first surface and some layer of electrically conductive material is disposed on the second surface at the opposite end of the second surface. The conductive material layers on the first and second surfaces constitute a first antenna operating at a first frequency of 915 MHz.

Several slots are provided in the conductive material layer of the first surface. The slot defines a second antenna operating at a second frequency greater than the first frequency. This second frequency may be 2450 MHz. The slot includes first and second slots extending in a direction intersecting with a relative direction of the conductive material layer on the first and second surfaces. The first and second slots have substantially the same length and are aligned with each other. The slot also includes third and fourth slots extending in the relative direction. The lengths of the first and second slots define the frequency of the signal from the second antenna, and the lengths of the third and fourth slots define the impedance of the second antenna. The third and fourth slots are spaced apart and in parallel to define the conducting portion.

An additional layer of conductive material is disposed on the first surface of the dielectric member to be in electrical communication with the conductive portion on the first surface. The additional conductive material layer is disposed opposite the conductive material layer on the second surface and is provided in a length defining the impedance of the first antenna.

In one embodiment of the invention, the antenna, generally labeled 10, comprises a dielectric member 12. Dielectric member 12 is made of a suitable material such as fiberglass and is provided in a relatively thin thickness of a 1/16 inch grade. Dielectric members may be provided with respect to parallel surfaces 14 and 16 which are disposed oppositely. Dielectric member 12 has a suitable length of approximately 6 1/2 inches and a suitable width of 2 inches.

The conductive material layer 18 may be disposed on the first surface 14 of the dielectric member 12. The conductive material layer 18 may be made of a thin sheet of a suitable material, such as copper, which may be covered with a suitable material, such as nickel solder. The first conductive material layer 18 may cover approximately one half of the area of the first surface 14. Similarly, another second conductive material layer 20 may cover approximately one half of the area of the second surface 16. In other words, each layer of conductive material 18, 20 has an appropriate length of approximately 3 1/4 inches and an appropriate width of approximately 2 inches. The second conductive material layer 20 is positioned on the second surface 16 of the dielectric member 12, but is staggered at opposite ends of the first conductive material layer 18. The conductive material layers 18 and 20 consist of a dipole antenna, generally indicated at 22 in FIG. This dipole antenna has a suitable frequency of about 915 MHz, which is preferable.

The slot 26 is provided in the conductive material layer 18. The slot 26 extends in a direction crossing with respect to the relative direction of the conductive material layers 18 and 20. Each slot 26 is approximately 3/4 inch long and 3/32 inch wide. The slots 26 substantially coincide with each other. The slots 26 are separated from each other by a conductive portion 28 having a width of approximately 1/16 inch.

At the end, each slot 26 has an extension extending in the relative direction of the conductive material layers 18, 20. Each slot extension 30 may have a length of approximately 1/2 inch and a width of 3/32 inch. Slot 26 and extension 30 constitute a second antenna having an appropriate frequency of approximately 2450 MHz.

인치의 적절한 거리로 확장하며, 3/16 인치의 폭을 가진다. 전도부(28)의 끝은 표면(14) 상의 도전 물질층(18)이 끝과 대체로 일치한다. 전도부(28)는 대략

인치의 길이와

인치의 폭을 갖는 각 슬로트(32)에 의해 구성된다. 전도부(28)의 칫수는 제2안테나의 임피던스를 규정한다.The conductive portion 28 is approximately in the relative direction of the conductive material layers 18 and 20.

Extend to an appropriate distance of inches and have a width of 3/16 inches. The ends of the conducting portions 28 generally coincide with the ends of the layer of conductive material 18 on the surface 14. Conduction part 28 is approximately

With the length of inches

Each slot 32 has a width of inches. The dimension of the conducting portion 28 defines the impedance of the second antenna.

An additional layer of conductive material, generally designated 36, extends from the conductive portion 28 along the first surface of the dielectric member 12. The additional conductive material layer 36 is disposed on the half where the conductive material layer 18 of the first surface 14 is not disposed. As a result, the additional conductive material layer 36 is disposed opposite the conductive material layer 20 on the second surface 16. The additional conductive material layer 36 preferably has a loop configuration composed by regions 40, 42, 44, 46, 48 and 50. These portions are approximately 1/8 inch wide and 1/8 inch, 3/4 inch, 3/8 inch, 1 inch, 3/8 inch and 1/4 inch respectively. The dimensions of the regions 40, 42, 44, 46, 48 and 50 define the impedance of the first antenna constituted by the conductive material layers 18 and 20.

4 shows the schematic principle of a dipole antenna constructed by conductive material layers 18, 20. As illustrated, the additional conductive material layer 36 is shown extending on the first surface 18 to the opposite end thereof, facing the conductive material layer 20 on the second surface. 5 shows an equivalent arrangement, in which the conductive material layers 18, 20 are configured as if they are coplanar, as shown in reference numerals 18a and 20a. Under such circumstances, the additional conductive material layer 36 is in a different plane, as indicated by 36a. The current flow then becomes the direction indicated by the image tables 50, 52 and 54 in the fifth illustration. The load 60 is considered to be connected between the conductive material layer 20a and the additional conductive material layer 36a.

As illustrated, there is a tendency to limit the amount of current provided to the dipole antenna constructed by the conductive material layers 18, 20 of the slot 26 in the conductive material layer 18. However, despite this limitation in the amount of current, the antenna constructed by the conductive material layers 18, 20 can provide a relatively large amount of current. However, this current limit is subtracted by the advantage of having a second antenna on the dielectric member 12.

Having two antennas in the antenna assembly 10 is advantageous because different frequencies are used for the transponders throughout the world. Frequencies of approximately 915 MHz are used in the United States, Europe and Hong Kong. The frequency of 2450 MHz is used in the Far East except Hong Kong. By providing two antennas on the antenna assembly 10 each having one of the frequencies, the antenna assembly 10 can be used anywhere in the world. Of course, as will be appreciated, the operation of the antenna at the frequency of 915 MHz provides a larger operating range than the antenna operating at the frequency of 2450 MHz, and therefore would be preferably used without being obstructed by government regulations.

An antenna composed of conducting portions 18, 20 provides a high voltage at the center of the surface 14, 16. The voltage at this antenna decreases in the longitudinal direction toward the outer sides of the conductive material layers 18 and 20. Similarly, the antenna at high frequencies provides a high voltage at the center of the slot 26 and a voltage that decreases toward the outside of the slot.

Antenna assembly 10 may be included in a transponder, generally indicated at 70 in FIG. Transponder 70 was Amfred R. July 14, 1987. It may be configured as fully disclosed and claimed in pending application number 885,250, filed in the name of Coele, and assigned to the assignee of the present application. Transponder 70 is attached to object 72 to transmit multiple signal periods to a reader (not shown) in separate codes that identify the object. This code can be identified by a separate combination of single periods at the first and second frequencies of 20 KHz and 40 KHz. The reader is Alfred Al Coele and inventor Jeremy A. on July 14, 1986. It may be configured as fully disclosed and claimed in pending application No. 885,248 filed in the name of Lant and assigned to the assignee of the present application.

Although disclosed and described with reference to specific embodiments of the present invention, it is apparent to those skilled in the art that the underlying principles are acceptable for use in many other embodiments. Therefore, the invention is limited only as indicated by the appended claims.

Claims (14)

A transponder antenna comprising: a thin planar dielectric member; One surface of the dielectric member may include a first conductive material layer in a first region on the first surface; A second conductive material layer of a second region on a second surface, which is another surface of the planar member, for forming a first antenna operating at a first frequency together with the second conductive material layer; And a plurality of slots included in the first conductive material layer to constitute a conductive portion; The conducting portion extends from the first region to a position of a first surface opposite the second region on the second surface and defines a second antenna operating at a second frequency higher than the first frequency; And the second region is moved from the position of the first region to the first direction along the surface of the dielectric member and is provided so as to cross each other. The method of claim 1, wherein the first layer of conductive material occupies half of the first surface on the dielectric member; And the second layer of conductive material occupies the other half of the second surface on the dielectric member. 3. The antenna of claim 2 wherein the slot is disposed in the conductive material layer on the first surface in a direction intersecting with the relative directions of the conductive material layers on the first and second surfaces of the dielectric member. 4. The slot of claim 3, wherein the slot has a portion extending in a direction coincident with the relative direction of the layer of conductive material on the first and second surfaces of the dielectric member, the portion affecting the impedance of antenna operation at a second frequency. An antenna having a length that impinges. A thin dielectric member having opposed first and second planar surfaces; A first conductive material layer positioned at a first end (left end) on the first surface of the dielectric member; And a second conductive material layer positioned at a second end (right end) at a position opposite to the first end on a second surface of the dielectric member; The first and second conductive material layers constitute a first antenna operating at a first frequency; And an interconnected plurality of slots provided in the layer of conductive material on the first surface to form a second antenna operating at a second frequency higher than the first frequency. 6. The method of claim 5, further comprising an additional conductive material layer overlying the first surface of the dielectric member and in a position opposite the conductive material layer of the second surface, wherein the additional conductive material layer is for the first antenna. An antenna configured to define a specific impedance. 6. The apparatus of claim 5, wherein the interconnected slots comprise: a first slot extending in a direction generally perpendicular to a relative direction of the conductive material layers on the first and second surfaces of the dielectric member; And a second slot extending from the first slot in the relative direction, respectively. The antenna of claim 7, wherein the second slots are connected to the first slots at positions where the first slots are closest to each other. 9. The apparatus of claim 8, wherein the second slots are arranged in a spatial and parallel relationship defining conducting portions between slots of length that define a specific impedance for the second antenna; An additional layer of conductive material on the first surface is in electrical communication with a conducting portion on the first surface. A thin plate dielectric member having first and second surfaces substantially in parallel: a first layer of conductive material at a first end (left end) on a first surface of the dielectric member; A second conductive material layer located at a second end (right end) at a position opposite to the first end on the second surface of the dielectric member, the second conductive material layer defining an antenna operating at a first frequency together with the first conductive material layer; ; A plurality of slots located in a first layer of conductive material on the first surface of the dielectric member, the second antenna operating at a second frequency higher than the first frequency, the plurality of slots having a specific impedance; And an additional layer of conductive material disposed on the first surface of the dielectric member that defines an impedance of the first antenna. 11. The method of claim 10, wherein the additional conductive material layer is positioned at a position opposite to the second conductive material layer and the material layer on the second surface of the dielectric member, characterized in that it is present on the first surface of the dielectric member. antenna. 12. The method of claim 11, wherein the slot in the first layer of conductive material on the first surface of the dielectric member constitutes a conductive portion, wherein the conductive portion has a length for controlling a specific impedance in the second antenna; And the conductive portion on the first surface of the dielectric member is in electrical communication with the layer of additional conductive material on the first surface of the dielectric member. 13. The antenna of claim 12 wherein the additional conductive material layer on the first surface of the dielectric member has a length that defines the impedance of the first antenna. 15. The layer of claim 13, wherein the additional conductive material layer on the first surface of the dielectric member is bent to increase the effective length of the additional conductive material layer within a limited region on the first surface of the dielectric member. An antenna, characterized in that.

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